JP2006254655A - Power controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce power consumption at the time of standby and to reduce cost and mounting space. <P>SOLUTION: An electric double layer capacitor 12 is connected to an output side of an AC/DC converter 11 as a main power supply. The electric double layer capacitor 12 is connected to an on/off control circuit 13 which on/off-controls the AC/DC converter 11. At the time of standby, power is supplied from the electric double layer capacitor 12 to the on/off control circuit 13 and the AC/DC converter 11 can be on/off-controlled. The on/off control circuit 13 incorporates an input voltage monitoring circuit 16. When voltage of the electric double layer capacitor 12 drops, the AC/DC converter 11 is temporarily turned on. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an AC / DC converter that converts an AC power source into a DC power source and supplies the device to an apparatus, and an on / off control circuit that turns on / off the AC / DC converter by an external signal.

  Conventionally, in electrical equipment such as household equipment, attempts have been made to reduce power consumption in a so-called standby state where the original operation of the equipment is not performed. For example, disclosed in JP-A-2002-32156 There is. This is to reduce power consumption during standby by setting a timer value when the main power is turned off and switching to the low consumption mode unless interrupt processing occurs while the timer value is counted.

  Also, in electronic devices that are always energized from a commercial power source and receive an activation signal from a remote controller, such as home video devices, attempts have been made to reduce power consumption during standby. A conventional power supply circuit having such a standby function is shown in FIG. This will be described in detail with reference to FIG.

  In FIG. 4, the electrical device 1 is connected to an AC power source 4 via an AC switch 2 and an AC / DC converter 3. The AC / DC converter 3 as the main power supply supplies power to the electric device 1 when turned on and stops supplying power when turned off. On / off control for the AC / DC converter 3 is performed by the receiving circuit 5. That is, the receiving circuit 5 transmits an on signal or an off signal to the AC / DC converter 3 when receiving a start signal or a stop signal from the remote controller.

The AC / DC converter 3 and the receiving circuit 5 are connected to a small capacity AC / DC converter 6 as a sub power source. During standby, the main power source AC / DC converter 3 is turned off, the sub power source AC / DC converter 6 is turned on, and the power source of the receiving circuit 5 is the sub power source AC / DC converter 6.
JP 2002-32156 A

  However, in the conventional power supply circuit shown in FIG. 4, the loss caused by switching the AC / DC converter 3 as the main power supply accounts for most of the loss of the low power supply. In the configuration shown in FIG. 4, since the AC / DC converter 6 of the sub power source must always be on in order for the receiving circuit 5 to turn on / off the AC / DC converter 3 during standby, it is useless during standby. Electricity was consumed. In addition, since the AC / DC converter 6 is required to secure the power supply during standby, the cost is increased and a mounting space is also required.

  Further, in the configuration disclosed in the above document, a secondary battery is used as standby power, but when a secondary battery is used as standby power, charging and discharging are repeated frequently. There has been a problem that the life is shortened and the life required by the apparatus cannot be satisfied.

  In order to solve the above-described problems, the present invention provides an AC / DC converter that converts an AC power source into a DC power source and supplies the device to an apparatus, and an on / off control circuit that turns the AC / DC converter on / off by an external signal The electric double layer capacitor is connected to the output side of the AC / DC converter and power is supplied from the electric double layer capacitor to the on / off control circuit during standby when no AC power is supplied. It is characterized by.

  In another aspect of the invention, the AC / DC converter is turned on when the AC power supply is supplied and turned off when the AC power supply is stopped. The relay circuit connected to the input side of the AC / DC converter and the AC / DC converter An electric double layer capacitor connected to the output side, and an on / off control circuit for supplying power from the electric double layer capacitor during standby when AC power is not supplied and controlling the relay circuit by an external signal are provided. It is characterized by this.

  According to the present invention having the above configuration, the electric double layer capacitor is charged by the electric power output from the AC / DC converter. During standby, electric power is supplied from the electric double layer capacitor to the on / off control circuit, and the AC / DC converter is off. The on / off control circuit can turn on / off the AC / DC converter by the supplied power. Since the AC / DC converter is in an off state during standby, no switching loss occurs and power consumption during standby can be reduced. In addition, since no sub-power supply is required, no mounting space is required and costs can be reduced.

  According to another invention, the AC / DC converter is turned on when the AC power supply is supplied and turned off when the AC power supply is stopped. In addition, the AC / DC converter is turned on / off by the power supplied from the electric double layer capacitor during standby. Since the control circuit controls the relay circuit connected to the input side of the AC / DC converter, the AC power supply and the device can be completely disconnected during standby, and the power consumption during standby can be reduced to zero. .

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a power supply control device according to a first embodiment of the present invention. In FIG. 1, a power supply control device 10 according to the first embodiment includes an input switch 17 connected to an AC power supply (commercial power supply) 4, an AC / DC converter 11 as a main power supply connected to the input switch 17, and an AC An electric double layer capacitor 12 is connected to the output side of the DC converter 11.

  An on / off control circuit 13 and an output switch 14 are connected to the electric double layer capacitor 12. The electric double layer capacitor 12 is one that can continue to supply power to the on / off control circuit 13 for several hours to several days. The output switch 14 controls power supply to the electric device 15.

  The on / off control circuit 13 performs on / off control for the AC / DC converter 11. The on / off control circuit 13 monitors a decrease in power supplied from the electric double layer capacitor 12 and transmits an on signal to the AC / DC converter 11 when a decrease in power is detected. 16 is built in. The on / off control circuit 13 also performs on / off control for the output switch 14. Further, an on signal for starting the device 15 or an off signal for turning off the device 15 is input to the on / off control circuit 13 from the outside, for example, from a remote controller.

  Next, the operation of the first embodiment will be described. FIG. 2 is a time chart showing a change in voltage of the electric double layer capacitor in the first embodiment. When the electrical device 15 is in operation, when an off signal is input to the on / off control circuit 13 from a remote controller (not shown), the on / off control circuit 13 sends an off signal to the AC / DC converter 11 as the main power source. To turn it off. Thereby, the electric apparatus 15 will be in a standby state. During standby, power is supplied from the electric double layer capacitor 12 to the on / off control circuit 13.

  When an on signal is input from the remote controller to the on / off control circuit 13 during standby, the on / off control circuit 13 transmits an on signal to the AC / DC converter 11 to turn on the AC / DC converter 11. . At the same time, the on / off control circuit 13 transmits an on signal to the output switch 14 to turn on the output switch 14 so that power can be supplied to the device 15. In FIG. 2, the on signal is input from the remote controller to the on / off control circuit 13 at the time points a, b, c, and d.

  As shown in FIG. 2, during standby, the voltage of the electric double layer capacitor 12 gradually decreases. Before the voltage of the electric double layer capacitor 12 decreases to the level A detected by the input voltage monitoring circuit 16 in the on / off control circuit 13, as shown at the above points a, b, c and d, the remote When an ON signal is input from the controller to the ON / OFF control circuit 13, the AC / DC converter 11 is turned on as described above, so that the electric double layer capacitor 12 is charged and the voltage rises to a predetermined level. The level is maintained while the device 15 is on.

  The electric double layer capacitor 12 can normally be supplied without being charged for several hours to several days. However, if the AC / DC converter 11 has not been turned on for a longer time, e time As shown, the power drops to the A level and is detected by the input voltage monitoring circuit 16 of the on / off control circuit 13. At this time, the input voltage monitoring circuit 16 transmits an ON signal to the AC / DC converter 11 to temporarily turn on the AC / DC converter 11.

  Since the electric double layer capacitor 12 has a short charging time, the electric double layer capacitor 12 can be sufficiently charged when the AC / DC converter 11 is in an ON state for several seconds. After the voltage of the electric double layer capacitor 12 is secured, the input voltage monitoring circuit 16 detects that the voltage of the electric double layer capacitor 12 is secured, and turns off the AC / DC converter 11.

  When the power is turned on for the first time or when the input switch 17 has been in an off state for a long time, the electric double layer capacitor 12 has an operation guaranteed voltage level B of the on / off control circuit 13 as indicated by f in FIG. It has decreased to the following. Therefore, in this state, the on / off control circuit 13 may become inoperable. In this case, the AC / DC converter 11 cannot be turned on from the on / off control circuit 13.

  However, when the input switch 17 is turned on, the AC / DC converter 11 is turned on, so that the electric double layer capacitor 12 is charged and returned to a voltage exceeding the guaranteed operating voltage level B as shown in FIG. Since the voltage of the electric double layer capacitor 12 is lowered by turning on the input switch 17 in a state where the electric double layer capacitor 12 is lower than the operation guarantee voltage level B, the AC / DC converter 11 automatically Turned on.

  As described above, according to the first embodiment, the AC / DC converter 11 is turned off during standby, so that no switching loss occurs during standby, and power consumption during standby can be reduced. . In addition, since no sub-power supply is required, the mounting space can be reduced and the cost can be reduced. Further, since the electric double layer capacitor 12 is used as a standby power source, deterioration due to repeated charging and discharging is reduced, and the life required by the apparatus can be satisfied.

  Next, a second embodiment will be described. FIG. 3 is a block diagram showing a power supply control apparatus according to the second embodiment. In FIG. 3, in the power supply control device 20 of the second embodiment, a two-contact non-lock switch 21 is used as an input switch, and a relay circuit 22 is connected in parallel with the two-contact non-lock switch 21. One contact 21a of the two-contact non-lock switch 21 and the relay circuit 22 are connected to an AC / DC converter 23 as a main power source.

  The AC / DC converter 23 is turned on when an AC voltage is input via the two-contact non-lock switch 21 or the relay circuit 22, and is turned OFF when an AC voltage is not input. As in the first embodiment, the electric double layer capacitor 12 is connected to the output side of the AC / DC converter 23, and the electric double layer capacitor 12 is connected to the output switch 14 and the on / off control circuit 24. Yes. As in the first embodiment, the electric double layer capacitor 12 is one that can continue to supply power to the on / off control circuit 24 for several hours to several days.

  The output switch 14 supplies power to the electric device 15 under the control of the on / off control circuit 24. The on / off control circuit 24 is connected to the other contact 21 b of the two-contact non-lock switch 21 and the gate 22 a of the relay circuit 22. The on / off control circuit 24 receives power from the electric double layer capacitor 12 and performs on / off control on the gate 22 a of the relay circuit 22.

  The on / off control circuit 24 includes an input voltage monitoring circuit 25 that monitors a decrease in power supplied from the electric double layer capacitor 12 and transmits an on signal to the relay circuit 22 when a decrease in power is detected. It has a built-in control function that turns off the output switch 14 when the two-contact non-lock switch 21 is pressed while the electric device 15 is on. The on / off control circuit 24 receives an on signal for starting up the device 15 or an off signal for turning off the device 15 from the outside, for example, from a remote controller.

  Next, the operation of the second embodiment will be described. This case will also be described with reference to the time chart shown in FIG. When the electrical device 15 is in operation, when an off signal is input to the on / off control circuit 24 from a remote controller (not shown), the on / off control circuit 24 transmits an off signal to the output switch 14 to turn it off. At the same time, an OFF signal is sent to the relay circuit 22 to turn off the relay circuit 22. Thereby, the electric apparatus 15 will be in a standby state.

  During standby, the relay circuit 22 and the two-contact non-lock switch 21 are off, so the AC / DC converter 23 is off. Thus, since the relay circuit 22 and the two-contact non-lock switch 21 are off during standby, the AC power supply 4 and the electric circuit are completely disconnected, and the power consumption is zero. Further, during standby, electric power is supplied from the electric double layer capacitor 12 to the on / off control circuit 24.

  When an on signal is input from the remote controller to the on / off control circuit 24 during standby, the on / off control circuit 24 transmits an on signal to the relay circuit 22 to turn on the relay circuit 22. As a result, an AC voltage is input to the AC / DC converter 23, and the AC / DC converter 23 is turned on. At the same time, the on / off control circuit 24 transmits an on signal to the output switch 14 to turn on the output switch 14 and supply power to the device 15. In FIG. 2, the ON signal is input from the remote controller to the ON / OFF control circuit 24 at the time points a, b, c, and d.

  As shown in FIG. 2, during standby, the voltage of the electric double layer capacitor 12 gradually decreases. Before the voltage of the electric double layer capacitor 12 drops to the level A detected by the input voltage monitoring circuit 25 in the on / off control circuit 24, as shown at the above points a, b, c, d, the remote When an ON signal is input from the controller to the ON / OFF control circuit 24, the AC / DC converter 23 is turned on as described above, so that the electric double layer capacitor 12 is charged and the voltage rises to a predetermined level. The level is maintained while the device 15 is on.

  The electric double layer capacitor 12 can normally be supplied without charging for several hours to several days. However, if the AC / DC converter 23 has not been turned on for a longer period of time, the time point e As shown, the power drops to the A level and is detected by the input voltage monitoring circuit 25 of the on / off control circuit 24. At this time, the input voltage monitoring circuit 25 transmits an ON signal to the relay circuit 22 to temporarily turn on the AC / DC converter 23.

  Since the electric double layer capacitor 12 has a short charging time, the electric double layer capacitor 12 can be sufficiently charged when the AC / DC converter 23 is in an ON state for several seconds. After the voltage of the electric double layer capacitor 12 is secured, the input voltage monitoring circuit 25 detects that the voltage of the electric double layer capacitor 12 is secured, turns off the relay circuit 22, and turns off the AC / DC converter 23. To.

  When the power is turned on for the first time or when an AC plug (not shown) is removed for a long time, the power supply control device 20 is completely disconnected from the AC power supply, and the electric double layer capacitor 12 is shown by f in FIG. The on / off control circuit 13 is lowered to the operation guarantee voltage level B or lower. Therefore, in this state, the on / off control circuit 13 may become inoperable. In this case, the AC / DC converter 11 cannot be turned on from the on / off control circuit 13.

  However, when the two-contact non-lock switch 21 is pressed, AC is temporarily supplied to the input side of the AC / DC converter 23, so that the electric double layer capacitor 12 is charged and the operation is guaranteed as shown in FIG. It returns to a voltage exceeding the voltage level B.

  Since the two-contact non-lock switch 21 is a switch that forcibly turns off the power when the device 15 malfunctions, the power is turned off by pressing the two-contact non-lock switch 21 when the device power is on. It has become a thing. By pressing the two-contact non-lock switch 21 once when the apparatus power is on, one pulse signal is input to the contact 21b of the two-contact non-lock switch 21 connected to the on / off control circuit 24. As a result, the on / off control circuit 24 issues an off signal to the output switch 14 to turn off the power supply to the device 15.

  As described above, according to the second embodiment, the AC / DC converter 23 is completely disconnected from the AC power supply 4 during the standby state and is turned off, so that no switching loss occurs during the standby period. It is possible to reduce power. Further, as in the first embodiment, since no sub-power supply is required, the mounting space can be reduced and the cost can be further reduced. Furthermore, since the electric double layer capacitor 12 is used as a power source during standby, deterioration due to repeated charging and discharging is reduced, and the life required by the apparatus can be satisfied.

It is a block diagram which shows the power supply control apparatus of 1st Embodiment. It is a time chart which shows the change of the voltage of the electric double layer capacitor in a 1st embodiment. It is a block diagram which shows the power supply control apparatus of 2nd Embodiment. It is a block diagram which shows the conventional power supply circuit.

Explanation of symbols

4 AC power supply 10 Power supply control device 11 AC / DC converter 12 Electric double layer capacitor 13 On / off control circuit 15 Electric device 16 Input voltage monitoring circuit

Claims (5)

In a power supply control device having an AC / DC converter that converts AC power into DC power and supplies the device to the device, and an on / off control circuit that turns on / off the AC / DC converter by an external signal,
An electric double layer capacitor is connected to the output side of the AC / DC converter, and power is supplied from the electric double layer capacitor to the on / off control circuit during standby when no AC power is supplied.   The on / off control circuit has detection means for detecting a power drop of the electric double layer capacitor, and turns on the AC / DC converter when the detection means detects a power drop of the electric double layer capacitor. The power supply control device according to claim 1, wherein the electric double layer capacitor is charged. In a power supply control device having an AC / DC converter that converts AC power into DC power and supplies the device to the device, and an on / off control circuit that turns on / off the AC / DC converter by an external signal,
The AC / DC converter is turned on when AC power is supplied and turned off when AC power is stopped.
A relay circuit connected to the input side of the AC / DC converter;
An electric double layer capacitor connected to the output side of the AC / DC converter;
An on / off control circuit for supplying power from the electric double layer capacitor during standby when no AC power is supplied and controlling the relay circuit by an external signal is provided.   The on / off control circuit has detection means for detecting a power drop of the electric double layer capacitor, and when the power drop of the electric double layer capacitor is detected by the detection means, the relay circuit is controlled to generate an alternating current. The power supply control device according to claim 3, wherein power is supplied to the AC / DC converter, thereby charging the electric double layer capacitor.   5. The power supply control device according to claim 3, further comprising a two-contact non-lock switch connected in parallel with the relay circuit.

Images